Balcioglu Aygul, Kim Mee-Ohk, Sharma Nutan, Cha Jang-Ho, Breakefield Xandra O, Standaert David G
MassGeneral Institute for Neurodegenerative Disease, Department of Neurology, Massachusetts General Hospital, Boston, Massachusetts, USA.
J Neurochem. 2007 Aug;102(3):783-8. doi: 10.1111/j.1471-4159.2007.04590.x. Epub 2007 Apr 30.
Early onset torsion dystonia, the most common form of hereditary primary dystonia, is caused by a mutation in the TOR1A gene, which codes for the protein torsinA. This form of dystonia is referred to as DYT1. We have used a transgenic mouse model of DYT1 dystonia [human mutant-type (hMT)1 mice] to examine the effect of the mutant human torsinA protein on striatal dopaminergic function. Analysis of striatal tissue dopamine (DA) and metabolites using HPLC revealed no difference between hMT1 mice and their non-transgenic littermates. Pre-synaptic DA transporters were studied using in vitro autoradiography with [(3)H]mazindol, a ligand for the membrane DA transporter, and [(3)H]dihydrotetrabenazine, a ligand for the vesicular monoamine transporter. No difference in the density of striatal DA transporter or vesicular monoamine transporter binding sites was observed. Post-synaptic receptors were studied using [(3)H]SCH-23390, a ligand for D(1) class receptors, [(3)H]YM-09151-2 and a ligand for D(2) class receptors. There were again no differences in the density of striatal binding sites for these ligands. Using in vivo microdialysis in awake animals, we studied basal as well as amphetamine-stimulated striatal extracellular DA levels. Basal extracellular DA levels were similar, but the response to amphetamine was markedly attenuated in the hMT1 mice compared with their non-transgenic littermates (253 +/- 71% vs. 561 +/- 132%, p < 0.05, two-way anova). These observations suggest that the mutation in the torsinA protein responsible for DYT1 dystonia may interfere with transport or release of DA, but does not alter pre-synaptic transporters or post-synaptic DA receptors. The defect in DA release as observed may contribute to the abnormalities in motor learning as previously documented in this transgenic mouse model, and may contribute to the clinical symptoms of the human disorder.
早发性扭转性肌张力障碍是遗传性原发性肌张力障碍最常见的形式,由TOR1A基因突变引起,该基因编码扭转蛋白A。这种形式的肌张力障碍被称为DYT1。我们使用了DYT1肌张力障碍的转基因小鼠模型[人类突变型(hMT)1小鼠]来研究突变型人类扭转蛋白A蛋白对纹状体多巴胺能功能的影响。使用高效液相色谱法分析纹状体组织中的多巴胺(DA)及其代谢产物,结果显示hMT1小鼠与其非转基因同窝小鼠之间没有差异。使用[³H]吗茚酮(一种膜多巴胺转运体的配体)和[³H]二氢丁苯那嗪(一种囊泡单胺转运体的配体)通过体外放射自显影研究突触前多巴胺转运体。未观察到纹状体多巴胺转运体或囊泡单胺转运体结合位点密度的差异。使用[³H]SCH-23390(一种D1类受体的配体)、[³H]YM-09151-2(一种D2类受体的配体)研究突触后受体。这些配体在纹状体结合位点的密度同样没有差异。在清醒动物中使用体内微透析技术,我们研究了基础状态以及苯丙胺刺激后的纹状体细胞外多巴胺水平。基础细胞外多巴胺水平相似,但与非转基因同窝小鼠相比,hMT1小鼠对苯丙胺的反应明显减弱(253±71%对561±132%,p<0.05,双向方差分析)。这些观察结果表明,导致DYT1肌张力障碍的扭转蛋白A蛋白突变可能会干扰多巴胺的转运或释放,但不会改变突触前转运体或突触后多巴胺受体。观察到的多巴胺释放缺陷可能导致此前在该转基因小鼠模型中记录的运动学习异常,并可能导致人类疾病的临床症状。
